A real-time optimal control method for swing-free tower crane motions

2013 IEEE International Conference on Automation Science and Engineering (CASE) Pub Date : 2013-11-07 DOI:10.1109/CoASE.2013.6653933

Wim Devesse, Marcus Ramteen, Lei Feng, J. Wikander

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引用次数: 13

Abstract

Tower cranes are commonly used at construction sites all over the world. These cranes are prone to swinging of the cable suspended payload, resulting in unwanted payload oscillations that have severe effects on the safety on the site as well as on operational speed and accuracy of the payload delivery. The nonlinear nature of the rotating crane motion makes controlling these oscillations a complex task. In this paper, a time-optimal velocity control method is developed to enable fast and swing-free tower crane movements by applying Pontryagin's maximum principle on a set of decoupled payload pendulum equations. The controller is developed in a feedback form and is implementable in real-time. The performance of the controller is compared with other control methods such as notch filtering and input shaping. Simulations using a detailed tower crane model show that time-optimal swing-free movements can be obtained and payload vibrations are reduced to levels lower than those that can be achieved with the other control methods, while resulting in significantly faster rise times in slew velocity.

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一种无摆动塔机运动实时最优控制方法

塔式起重机是世界各地建筑工地普遍使用的起重机。这些起重机很容易摇摆缆索悬挂的有效载荷，导致不必要的有效载荷振荡，这对现场的安全以及有效载荷交付的操作速度和准确性产生严重影响。旋转起重机运动的非线性特性使得控制这些振荡成为一项复杂的任务。本文将庞特里亚金极大值原理应用于一组解耦载荷摆方程，提出了一种塔机快速无摆运动的时间最优速度控制方法。该控制器采用反馈形式开发，可实时实现。并与陷波滤波、输入整形等控制方法进行了性能比较。利用塔机模型进行的详细仿真表明，该控制方法可以实现无摆动的时间最优运动，有效载荷振动降低到低于其他控制方法所能达到的水平，同时回转速度的上升时间明显加快。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2013 IEEE International Conference on Automation Science and Engineering (CASE)

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